Your search keyword '"Fujino Obata"' showing total 13 results

1. Optimized Crystal Surface Treatment for Crosshair Light-Sharing TOF-DOI PET Detector

Author

Eiji Yoshida, Han Gyu Kang, Fujino Obata, and Taiga Yamaya

Subjects

Radiology, Nuclear Medicine and imaging, Instrumentation, Atomic and Molecular Physics, and Optics

Published

2023

2. Development of a Two-Layer Staggered GAGG Scatter Detector for Whole Gamma Imaging

Author

Sodai Takyu, Hideaki Tashima, Taiga Yamaya, Fujino Obata, Kei Kamada, Eiji Yoshida, Akira Yoshikawa, and Fumihiko Nishikido

Subjects

Physics, Gamma imaging, Optics, business.industry, Detector, Two layer, Radiology, Nuclear Medicine and imaging, Development (differential geometry), business, Instrumentation, Atomic and Molecular Physics, and Optics

Published

2022

3. A Crosshair Light Sharing PET Detector With DOI and TOF Capabilities Using Four-to-One Coupling and Single-Ended Readout

Author

Eiji Yoshida, Kei Kamada, Taiga Yamaya, and Fujino Obata

Subjects

Coupling, Scintillation, Materials science, Image quality, business.industry, Photoelectric sensor, Detector, Resolution (electron density), Atomic and Molecular Physics, and Optics, Crystal, Optics, Radiology, Nuclear Medicine and imaging, business, Instrumentation, Energy (signal processing)

Abstract

To improve positron emission tomography (PET) image quality, depth-of-interaction (DOI) information and time-of-flight (TOF) information are key technologies. In this work, we developed the DOI-TOF detector based on our original single-ended readout scheme with the continuous layered gadolinium fine aluminum garnet (GFAG) array. The size of each GFAG crystal is $1.45\times 1.45\times 20$ mm3. The multipixel photon counter (MPPC) used as a photo sensor has a surface area of $3.0\times 3.0$ mm2. One pair of crystals coupled with a partial optical window is arranged across two MPPCs. Boundaries without the partial optical window are covered with optical reflectors. Each pair is coupled with paired MPPCs of different patterns. Crystal identification is obtained from paired MPPCs of different patterns and output rates. By limiting the spread of scintillation light, the proposed DOI detector based on the local centroid calculation was expected to improve crystal response, including the edge. For performance comparison, we prepared three discrete layers of the GFAG array with the same total thickness. For the continuous layer, the DOI resolution, the energy resolution and the timing resolution of the pair of detectors are 4.7 mm, 14%, and 402 ps, respectively. Their respective values are 29%, 20%, and 33% better than those with the three discrete layers.

Published

2021

4. 核医学用シンチレータの多様性

Author

Han Gyu, Kang, Go, Akamatsu, Sodai, Takyu, Kang, Hangyu, Fujino, Obata, Eiji, Yoshida, and Taiga, Yamaya

Abstract

多様な核医学用シンチレータについて、ごく簡単に概説した。

Published

2021

5. A Crosshair Light Sharing PET Detector With DOI and TOF Capabilities Using Four-to-One Coupling and Single-Ended Readout

Author

Eiji, Yoshida, Fujino, Obata, Kamada, Kei, and Taiga, Yamaya

Abstract

To improve positron emission tomography (PET) image quality, depth-of-interaction (DOI) information and timeof-flight (TOF) information are key technologies. In this work, we developed the DOI-TOF detector based on our original singleended readout scheme with the continuous layered gadolinium fine aluminum garnet (GFAG) array. The size of each GFAG crystal is 1.45×1.45×20 mm3. The multi-pixel photon counter (MPPC) used as a photo-sensor has a surface area of 3.0×3.0 mm2. One pair of crystals coupled with a partial optical window is arranged across two MPPCs. Boundaries without the partial optical window are covered with optical reflectors. Each pair is coupled with paired MPPCs of different patterns. Crystal identification is obtained from paired MPPCs of different patterns and output rates. By limiting the spread of scintillation light, the proposed DOI detector based on the local centroid calculation was expected to improve crystal response including the edge. For performance comparison, we prepared three discrete layers of the GFAG array with the same total thickness. For the continuous layer, the DOI resolution, the energy resolution and the timing resolution of the pair of detectors are 4.7 mm, 14% and 402 ps, respectively. Their respective values are 29%, 20% and 33% better than those with the three discrete layers.

Published

2020

6. Development of Single-Ended Readout DOI Detector With Quadrisected Crystals

Author

Taiga Yamaya, Eiji Yoshida, Kei Kamada, and Fujino Obata

Subjects

Materials science, business.industry, Photoelectric sensor, Detector, Resolution (electron density), chemistry.chemical_element, Integrated circuit, Atomic and Molecular Physics, and Optics, law.invention, Crystal, Silicon photomultiplier, Optics, chemistry, law, Radiology, Nuclear Medicine and imaging, Gallium, business, Instrumentation, Energy (signal processing)

Abstract

In this article, we developed the novel single-end readout depth-of-interaction (DOI) detector with quadrisected crystals comparable in size to a single photo sensor. The proposed DOI detector consists of 784 gadolinium aluminum gallium garnet (GAGG) crystals, which are arranged in four layers of $14\times14$ arrays coupled with an $8\times8$ multipixel photon counter (MPPC) array. The size of each GAGG crystal is $1.45\times 1.45\times4.5$ mm3. Also, each MPPC has a surface area of $3.0\times3.0$ mm2. One pair of four-layered crystals coupled with a partial optical window is arranged across two MPPCs. Boundaries without the partial optical window are covered with optical reflectors. Light sharing is done between a pair of four-layered crystals optically coupled at one end. Each pair is coupled with paired silicon photomultipliers of different patterns. Crystal identification from each pair is obtained from the output rate of two MPPCs. From 511-keV uniform irradiation, responses of all crystal elements in the four layers can be separated clearly on a 2-D position histogram after applying the Anger calculation. Also, DOI information can be mapped to each cluster on curved lines. The energy resolution for all crystals is 9.1% after event reduction of intercrystal scatter.

Published

2020

7. Development of Single-Ended Readout DOI Detector With Quadrisected Crystals

Author

Yoshida, Eiji, Obata, Fujino, Kamada, Kei, Yamaya, Taiga, Eiji, Yoshida, Fujino, Obata, and Taiga, Yamaya

Abstract

—In this article, we developed the novel single-end readout depth-of-interaction (DOI) detector with quadrisected crystals comparable in size to a single photo sensor. The proposed DOI detector consists of 784 gadolinium aluminum gallium garnet (GAGG) crystals, which are arranged in four layers of 14 × 14 arrays coupled with an 8 × 8 multipixel photon counter (MPPC) array. The size of each GAGG crystal is 1.45 × 1.45 × 4.5 mm3. Also, each MPPC has a surface area of 3.0 × 3.0 mm2. One pair of four-layered crystals coupled with a partial optical window is arranged across two MPPCs. Boundaries without the partial optical window are covered with optical reflectors. Light sharing is done between a pair of four-layered crystals optically coupled at one end. Each pair is coupled with paired silicon photomultipliers of different patterns. Crystal identification from each pair is obtained from the output rate of two MPPCs. From 511-keV uniform irradiation, responses of all crystal elements in the four layers can be separated clearly on a 2-D position histogram after applying the Anger calculation. Also, DOI information can be mapped to each cluster on curved lines. The energy resolution for all crystals is 9.1% after event reduction of intercrystal scatter.

Published

2020

8. Feasibility of triple gamma ray imaging of

Author

Akram, Mohammadi, Hideaki, Tashima, Sodai, Takyu, Yuma, Iwao, Go, Akamatsu, Han Gyu, Kang, Fujino, Obata, Fumihiko, Nishikido, Katia, Parodi, and Taiga, Yamaya

Subjects

Gamma Rays, Phantoms, Imaging, Feasibility Studies, Humans, Polymethyl Methacrylate, Tomography, X-Ray Computed, Monte Carlo Method

Published

2022

9. Simultaneous time-skew and time-walk correction for TOF-PET detector

Author

Eiji Yoshida, Fujino Obata, and Taiga Yamaya

Subjects

Nuclear and High Energy Physics, Instrumentation

Published

2023

10. Gapless implementation of crosshair light-sharing PET detector

Author

Eiji, Yoshida, Fujino, Obata, Kamada, Kei, Yoshikawa, Akira, Taiga, Yamaya, Eiji, Yoshida, Fujino, Obata, Kamada, Kei, Yoshikawa, Akira, and Taiga, Yamaya

Abstract

Recently, silicon photomultipliers (SiPMs) have become established as photo-sensors for PET scanners. Commercially available SiPM arrays are typically about 3–4 cm in size. In order to develop larger detectors with an Anger calculation, multiple SiPM arrays need to be combined. This configuration requires the use of a light guide and has inactive areas between SiPM arrays. If not addressed, crystal identification degrades not only for peripheral crystals but also for crystals to bridge the gap between the SiPM arrays. On the other hand, we have developed the crosshair light-sharing (CLS) PET detector, which is based on a single-ended readout scheme with roughly quadrisected crystals comparable in size to a SiPM, with depth-of-interaction (DOI) capability. The CLS PET detector based on the local centroid calculation was expected to mitigate the edge effect similar to what the one-to-one coupling detector is able to do. In this work, we developed the axially long CLS PET detector with two multipixel photon counter (MPPC) arrays. The proposed long CLS PET detector consisted of 30 × 14 gadolinium fine aluminum garnet (GFAG) arrays coupled to two 8 × 8 MPPC arrays without the light guide. From 511-keV uniform irradiation, responses of all crystal elements could be separated clearly on a 2D position histogram after applying the Anger calculation. Pulse heights of additional crystals to bridge the gap were 18% lower than those of crystals at the center of the MPPC array, but similar to that of the peripheral crystals based on non-uniformity of the MPPC array. On the other hand, energy resolutions of additional crystals to bridge the gap were almost the same to those of other crystals. The long CLS PET detector promises improvement of the packing fraction while keeping performance.

Published

2022

11. Development of a Two-layer Staggered GAGG Scatter Detector for Whole Gamma Imaging

Author

Sodai, Takyu, Eiji, Yoshida, Fumihiko, Nishikido, Fujino, Obata, Hideaki, Tashima, Kamada, Kei, Yoshikawa, Akira, and Taiga, Yamaya

Subjects

Physics::Instrumentation and Detectors

Abstract

Silicon photomultiplier (SiPM) based scintillation detectors are widely used for positron emission tomography (PET), but their application to Compton cameras should be further explored. Whole gamma imaging (WGI) is a combination of PET and a Compton camera realized by inserting a scatter detector ring into a PET ring. In a previous study, we developed a WGI prototype in which the scatter detector consists of Gd3Al2Ga3O12:Ce (GAGG) scintillators coupled with SiPM for a proof-of-concept. However, its Compton imaging performance was not as good as its PET imaging performance. In this paper, we developed a two-layer staggered GAGG scatter detector which was optimized for WGI. GAGG crystals 1.45×1.45×4.5 mm3 in size were arranged into a 13×13 array for the 1st layer and a 14×14 array for the 2nd layer with a staggered arrangement. The two-layer crystal block was optically coupled to an 8×8 SiPM array (3 mm pixel). Using radioactive sources with different energies, we investigated the energy resolution performance experimentally. Almost all crystals were clearly separated in the flood histogram at multiple energies. The developed detector showed energy resolutions of 7.7% to 8.5% at 511 keV, which was better than that of the detector of the current WGI prototype. The next generation WGI system was modeled in simulations using the obtained energy resolution data. The simulation results showed that the WGI with the developed detector had 1.2 times better sensitivity and better angular resolution in the peripheral region than the current WGI prototype.

Published

2021

12. Development of crosshair light sharing PET detector with TOF and DOI capabilities using fast LGSO scintillator

Author

Eiji, Yoshida, Fujino, Obata, Kamada, Kei, Yoshikawa, Akira, Taiga, Yamaya, Eiji, Yoshida, Fujino, Obata, Kamada, Kei, Yoshikawa, Akira, and Taiga, Yamaya

Abstract

Objective. Time-of-flight (TOF) and depth-of-interaction (DOI) are well recognized as important information to improve PET image quality. Since such information types are not correlated, many TOF-DOI detectors have been developed but there are only a few reports of high-resolution detectors (e.g. 1.5 mm resolution) for brain PET systems. Based on the DOI detector, which enables single-ended readout by optically coupling a pair of crystals and having a loop structure, we have developed the crosshair light sharing (CLS) PET detector that optically couples the four-loop structure, consisting of quadrisected crystals comparable in size to a photo-sensor, to four photo-sensors in close proximity arranged in a windmill shape. Even as a high-resolution detector, the CLS PET detector could obtain both TOF and DOI information. The coincidence resolving time (CRT) of the CLS PET detector needs to be further improved, however, for application to the brain PET system. Recently, a fast LGSO crystal was developed which has advantages in detection efficiency and CRT compared to the GFAG crystal. In this work, we developed the CLS PET detector using the fast LGSO crystal for the TOF-DOI brain PET system. Approach. The crystals were each 1.45 × 1.45 × 15 mm3 and all surfaces were chemically etched. The CLS PET detector consisted of a 14 × 14 crystal array optically coupled to an 8 × 8 MPPC array. Main results. The fast LGSO array provided 10.1% energy resolution at 511 keV, 4.7 mm DOI resolution at 662 keV, and 293 ps CRT with the energy window of 440–620 keV. Significance. The developed CLS PET detector has 290% higher coincidence sensitivity, 30% better energy resolution, and 32% better time resolution compared to our previous CLS PET detector.

Published

2021

13. Gapless implementation of crosshair light-sharing PET detector

Author

Eiji Yoshida, Taiga Yamaya, Akira Yoshikawa, Kei Kamada, and Fujino Obata

Subjects

Physics, Coupling, Nuclear and High Energy Physics, business.industry, Detector, Centroid, Atomic packing factor, Crystal, Silicon photomultiplier, Gapless playback, Optics, business, Instrumentation, Energy (signal processing)

Abstract

Recently, silicon photomultipliers (SiPMs) have become established as photo-sensors for PET scanners. Commercially available SiPM arrays are typically about 3–4 cm in size. In order to develop larger detectors with an Anger calculation, multiple SiPM arrays need to be combined. This configuration requires the use of a light guide and has inactive areas between SiPM arrays. If not addressed, crystal identification degrades not only for peripheral crystals but also for crystals to bridge the gap between the SiPM arrays. On the other hand, we have developed the crosshair light-sharing (CLS) PET detector, which is based on a single-ended readout scheme with roughly quadrisected crystals comparable in size to a SiPM, with depth-of-interaction (DOI) capability. The CLS PET detector based on the local centroid calculation was expected to mitigate the edge effect similar to what the one-to-one coupling detector is able to do. In this work, we developed the axially long CLS PET detector with two multipixel photon counter (MPPC) arrays. The proposed long CLS PET detector consisted of 30 × 14 gadolinium fine aluminum garnet (GFAG) arrays coupled to two 8 × 8 MPPC arrays without the light guide. From 511-keV uniform irradiation, responses of all crystal elements could be separated clearly on a 2D position histogram after applying the Anger calculation. Pulse heights of additional crystals to bridge the gap were 18% lower than those of crystals at the center of the MPPC array, but similar to that of the peripheral crystals based on non-uniformity of the MPPC array. On the other hand, energy resolutions of additional crystals to bridge the gap were almost the same to those of other crystals. The long CLS PET detector promises improvement of the packing fraction while keeping performance.

Published

2022